Article pubs.acs.org/JAFC
Determination of Starch Lysophospholipids in Rice Using Liquid Chromatography−Mass Spectrometry (LC-MS) Lei Liu,*,† Chuan Tong,§ Jinsong Bao,*,§ Daniel L. E. Waters,† Terry J. Rose,†,# and Graham J. King† †
Southern Cross Plant Science, Southern Cross University, Lismore, NSW 2480, Australia Institute of Nuclear Agricultural Sciences, Key Laboratory of Zhejiang Province and Chinese Ministry of Agriculture for Nuclear-Agricultural Sciences, Zhejiang University, Hangzhou 310029, China # Southern Cross GeoScience, Southern Cross University, Lismore, NSW 2480, Australia §
S Supporting Information *
ABSTRACT: Acquiring a complete understanding of rice starch lysophospholipids (LPLs), their biosynthetic pathways and genetic diversity, and the influence of genotype by environment interactions has been hampered by the lack of efficient highthroughput extraction and analysis methods. It was hypothesized a single-step aqueous n-propanol extraction combined with liquid chromatography−mass spectrometry (LC-MS) could be employed to analyze starch LPLs in white rice. The investigation found different grinding methods showed little effect on the final LPL detected, and a simple single-step extraction with 75% npropanol (8 mL/0.15 g) heated at 100 °C for 2 h was as effective as an onerous multistep extraction method. A LC-MS method was optimized to simultaneously quantify 10 major LPLs in rice starch within 15 min. This method enables total and individual starch LPL analysis of a large number of rice samples at little cost. This approach could be applied to starch LPLs in other cereals. KEYWORDS: rice, lysophospholipid, LC-MS, starch lipid, amylose−lipid complex, grain quality
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INTRODUCTION Cereal starch granules contain endogenous lipids that occur both within and on the surface of starch granules.1 The starch lipids in this paper refer to those that naturally form inclusion complexes with starch, and amylose in particular, inside the granules.2 Starch lipids are important because they interact with starch and modify product texture, rheological properties, digestibility, and storage stability.3−5 Cereal starch lipids are mainly monoacyl lipids, such as free fatty acids and lysophopolipids (LPLs, see the Supporting Information for the structures).1 The starch LPLs account for about 50% of the starch lipids in rice and are of particular interest to us because they contain bioavailable nutrients such as phosphate, choline, and ethanolamine.6 We recently systematically reviewed the literature on rice phospholipids and evaluated their significance in grain quality and contribution to human health benefits.6 Although rice starch LPLs are not major sources of dietary phospholipids as are oilseeds, eggs, or seafood, they may play an important role for some modern concepts of rice qualities such as glycemic index.6 In addition, LPLs may have an important role in starch biosynthesis and hence affect rice quality. However, there are few reports concerning these LPLs in cereals, which is partially due to the lack of an efficient analytical method. Rice starch LPLs have previously been analyzed using a combination of classical thin layer chromatography (TLC) and gas chromatography (GC) methods.7 The major rice starch LPLs were found to be lysophosphatidylcholine (LPC) and lysophosphatidylethanolamine (LPE). The fatty acid compositions of these LPLs are mainly palmitic (16:0, 48−63%) and linoleic (18:2, 25−42%) acids, with minor contributions from oleic (18:1, ∼5%) and myristic (14:0, ∼5%) acids.7 The TLCGC method usually requires extraction from large sample sizes © 2014 American Chemical Society
(∼100 g). Moreover, the sample preparation process is timeconsuming with many steps, which can lead to errors in the final results. To investigate the biosynthetic pathways of rice LPLs, their natural and induced genetic diversity, and the extent to which they are subject to genotype by environment interactions, a large number (500−1000) of small quantity ( 3). The limit of quantification (LOQ) was defined as the concentration of LPL that was required to produce a signal >10 times the standard deviation of the noise level (S/N > 10). The signal-tonoise ratio (S/N) was calculated using Agilent Chemstation software (rev. B04.03). Under the LC-MS conditions used in this study, the LOD was about 6 pM (about 3 pg/mL) and the LOQ was about 30 pM (about 15 pg/mL). On the basis of the current extraction and sample preparation methods, we can detect and quantify each LPL when its concentration in the rice grain is >0.75 ng/g (about 1 ppb). The R2 values of the LPL standard curves were all >0.9996 over the working concentration range (between 32 and 200,000 pM). The precision of the instrument was determined by injecting a standard mix solution six times (n = 6). The average of the relative standard deviation (RSD) values for each LPL was about 1% of the six repeated analyses. Total Starch LPLs by Multistep Extraction. The 10 major starch LPLs extracted by the second-step extraction of the multistep extraction were quantified using the LC-MS method above and added together as the total starch LPLs. The total starch LPLs (from R01CS−R02CS and R01BS−R02BS, Figure 1) varied between 516 and 675 μg/g for the waxy rice (or glutinous rice, amylose content